Feedback information for controlling transmission in a communication system
A method is discussed for generating feedback information for controlling transmission from a transmitting end using a set of feedback symbols. The feedback information comprises a set of feedback words. At least one feedback symbol is determined based on at least one signal received from the transmitting end. A feedback word to be transmitted to the transmitting end is determined, the feedback word relating to the determined feedback symbol, by a mapping between said set of feedback symbols and said set of feedback words. This mapping takes into account the effect of at least one possible transmission error in transmitting the feedback word to the transmitting end. Furthermore, the mapping is different from a mapping relating to Gray encoding.
Latest Patents:
The present invention relates to providing feedback information in a wireless communication system. In particular, the present invention relates to providing feedback information for controlling transmission.
BACKGROUND OF THE INVENTIONA communication system can be seen as a facility that enables communication between two or more entities such as user equipment and/or other nodes associated with the system. The communication may comprise, for example, communication of voice, data, multimedia and so on. The communication system may be circuit switched or packet switched. The communication system may be configured to provide wireless communication.
At least some signaling is typically required in order to control a communication session. Communication between the user equipment and the entities of the communication network and the signaling can be based on an appropriate communication protocol or protocols.
Feedback information is needed for controlling the transmission in many communication systems. Especially in frequency division duplex (FDD) systems, where transmission and reception occur at different frequencies, it may not be possible to deduce channel information of a channel, on which a device transmits to a second device, based on a channel, on which signals are received from the second device. In time division duplex (TDD) systems, transmission and reception occur at the same frequency, so channel information is usually readily available.
Feedback information may relate to transmission power control or to control of transmission more generally. Often feedback information is related to a continuous quantity, or otherwise an ordering is induced. This means that one may define a metric in the space of feedback symbols relaying feedback information so that some possible feedback symbols are closer neighbors than some others. If the feedback is based on a continuous quantity, the corresponding metric may be taken as a Euclidean metric in the space of the continuous quantities. For example, in many transmit diversity methods, where the phase difference between two or more signals sent from two or more antennas is adjusted, feedback information is needed for proper adjustment of the phase difference. Feedback information may also be used to control both phase and amplitude of transmission. In these cases, the metric defining proximity may be taken as the Euclidean metric on the plane.
When feedback information is conveyed from the receiving end of the communication link to the transmitting end, digital communication is often used. For this, the feedback information describing continuous quantities has to be quantized using a predefined quantization method. Such quantized numbers are often called feedback symbols. Typically feedback symbols are then described in terms of a set of binary feedback words. Information about this feedback symbol is sent to the transmitter by sending the determined feedback word as feedback signaling. After receiving the binary feedback signaling, the transmitter controls transmission. Often the transmitter constructs the feedback symbols from the received feedback signaling i.e. quantized estimates of the continuous quantities (phase, amplitude, complex number) and uses them directly to control transmission. For example, phase shift keying modulation symbols may be used to indicate how to modify the phase difference of two signals sent to a receiver. Usually a mapping called Gray encoding is used for transmitting signaling information and for transmitting feedback information.
Usually information to be transmitted over a wireless link is protected against transmission errors. This protection can be performed, for example, by adding some error detection/correction codes or by adding redundancy by partially repeating the information to be transmitted. Feedback signaling is typically unprotected for enabling fast transmission of the feedback information and for saving transmission resources. This means that feedback signaling is error-prone. A bit error in feedback information may result in the use of a wrong feedback symbol in transmission control. For example in WCDMA (Wideband Code Division Multiple Access) standardization it is assumed that that the bit error rates (BER) for unprotected feedback signaling is about 4-10%.
To overcome at least some of the problems relating to bit errors in transmitting feedback information, a concept of verification has been introduced in some diversity methods, for example in Mode 2 diversity in WCDMA system. In verification the receiver tries, after sending feedback information, to deduce from the signals sent by the transmitter which feedback symbol the transmitter is employing in the transmission control. The verification is typically based on pilot signals (or other signals whose information content is known to the receiver) and on the signals whose transmission is controlled using the feedback information. As the verification is based on estimation of various signals, possible measurement errors and poor estimation accuracy affect the accuracy of verification. In WCDMA mode 2, verification typically detects only half of the situations, where a bit error in a feedback word has caused a wrong feedback symbol to be used in transmission control. It should be noted that in those cases, where verification does not detect the use of a wrong feedback symbol, the receiver typically cannot receive information properly. In such cases the use of feedback actually degrades the performance of the system.
Furthermore, errors in feedback information may cause a transmitter to use an unnecessary high transmission power for a certain receiver. This typically causes interference to other receivers.
Regarding WCDMA, it is furthermore noted that WCDMA has two different modes: mode 1 and mode 2. Signal to a receiver may be sent from two antennas of a base station of WCDMA. Either the phase difference of the two signals relating to the two antennas is adjusted while keeping the ratio of the transmission powers fixed (mode 1), or both the phase difference and the amplitudes are adjusted (mode 2). In mode 1, 2-bit feedback words indicate one of four possible phase differences. In mode 2, 4-bit feedback words are needed. Three bits of a feedback word indicate one of eight possible phase differences, and one bit indicates one of two possible amplitude ratios. As mode 2 provides a more sophisticated feedback method, it is expected that the system performance is enhanced by using mode 2 instead of mode 1.
There are thus problems relating to the transmission of feedback information over a noisy channel.
An aim of the present invention is to provide a more reliable method for transmitting feedback information.
SUMMARY OF THE INVENTIONIn accordance with a first aspect of the invention, there is provided a method for generating feedback information for controlling transmission from a transmitting end using a set of feedback symbols, said feedback information comprising a set of feedback words, the method comprising:
-
- determining at least one feedback symbol based on at least one signal received from a transmitting end; and
- determining a feedback word to be transmitted to the transmitting end, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account the effect of at least one possible transmission error in transmitting the feedback word to the transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
In accordance with a second aspect of the invention, there is provided a method of transmitting a feedback word to a transmitting end, the method comprising:
-
- determining at least one feedback symbol based on at least one signal received from a transmitting end;
- determining a feedback word to be transmitted to the transmitting end, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding; and
- transmitting the determined feedback word to the transmitting end.
In accordance with a third aspect of the invention, there is provided a method for receiving feedback information for controlling transmission from a transmitting end using a set of feedback symbols, said feedback information comprising a set of feedback words, the method comprising:
-
- receiving a feedback word; and
- determining a feedback symbol relating to a received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account the effect of at least one possible transmission error in transmitting a feedback word to a transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
In accordance with a fourth aspect of the invention, there is provided a method of controlling transmission, said method comprising:
-
- receiving a feedback word;
- determining a feedback symbol relating to a received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting a feedback word to a transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding; and
- controlling transmission from the transmitting end based on a determined feedback symbol.
In accordance with a fifth aspect of the invention, there is provided a device for generating feedback information for controlling transmission from a transmitter using a set of feedback symbols, said feedback information comprising a set of feedback words, the device being configured to determine a feedback symbol based on at least one signal received from the transmitter, and to determine a feedback word to be transmitted, said feedback word relating to a determined feedback symbol, using a mapping between said set of feedback symbols and said set of feedback words that takes into account the effect of at least one possible transmission error in transmitting the feedback word to the transmitter, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
In accordance with a sixth aspect of the invention, there is provided a device for receiving feedback information for controlling transmission from a transmitter using a set of feedback symbols, said feedback information comprising a set of feedback words, said set of feedback words being mapped onto said set of feedback symbols, the device being configured to receive a feedback word, and to determine a feedback symbol relating to a received feedback word using a mapping between said set of feedback symbols and said set of feedback words that takes into account the effect of at least one possible transmission error in transmitting the received feedback word, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
In accordance with a seventh aspect of the invention, there is provided a device comprising:
-
- first determining means for determining a feedback symbol based on at least one signal received from a transmitting end; and
- second determining means for determining a feedback word to be transmitted to the transmitting end, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
In accordance with an eighth aspect of the invention, there is provided a device comprising:
-
- receiving means for receiving a feedback word; and
- determining means for determining a feedback symbol relating to the received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting a feedback word to a transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
In accordance with a ninth aspect of the invention, there is provided a communication system comprising a first device for generating feedback information for controlling transmission from a second device comprised in the communications system,
- the first device being configured
- to determine a feedback symbol based on at least one signal received from the second device, and
- to determine a feedback word to be transmitted, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the second device, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding, and the second device being configured
- to receive a feedback word, and
- to determine a feedback symbol relating to a received feedback word using said mapping between said set of feedback symbols and said set of feedback words.
The feedback word may be a binary feedback word, and the mapping may be a mapping minimizing an average square Euclidean distance of feedback symbol errors ensuing from a given number of feedback bit errors. The mapping may further minimize the maximum Euclidean distance of feedback symbol errors ensuing from the given number of feedback bit errors within a set of mappings minimizing the average square Euclidean distance of feedback symbols errors ensuing from a given number of feedback bit errors.
The feedback words may be at least three bits long and the feedback symbols of may define various phases. Alternatively, the feedback words may be at least two bits long and the feedback symbols may define various amplitudes. As a further example, the feedback words may be at least two bits long and the feedback symbols may define various amplitude and phase combinations. Furthermore, a feedback word may comprise an at least two bits long first feedback word relating to various amplitudes and an at least one bit long second feedback word, where the first feedback word is determined using the mapping. As a further example, the feedback word may comprise an at least three bits long first feedback word relating to various phases and an at least one bit long second feedback word, and the first feedback word is determined using the mapping.
The determined feedback symbol may be used directly in controlling transmission. In this case, the determined feedback symbol may define an absolute change to transmission or a differential change to transmission. A further option is to determine channel properties estimated at a receiving end based on the feedback symbol and control transmission based on the determined channel properties.
A device for generating feedback information for controlling transmission from a transmitter or a device for receiving feedback information for controlling transmission may be a network element for a communications system or a communications device, for example a mobile station or user equipment, for communicating via the communications system.
Embodiments of the invention may improve performance of a system, where feedback information is transmitted, compared to using Gray encoding for transmitting feedback information. The increase in reliability comes without a complexity increase, as only the mapping between the feedback words and the feedback symbols needs to be modified. After modifying the mapping, there is no need to modify any parts of a transmitter, of a receiver or of a communication system for implementing embodiment of the present invention.
BRIEF DESCRIPTION OF THE DRAWINGSEmbodiments of the present invention will now be described by way of example only with reference to the accompanying drawings, in which:
For better understanding of the examples, details of the feedback control for transmission diversity are first discussed. Lets consider a signal sent on two channels h1 and h2. The received transmission power is |w1h1+w2h2|, where the weights wi and the channel coefficients hi are complex numbers. In a selection transmission diversity (STD), one of the two channels is chosen. Typically the selected channel is the one, where a receiver is receiving a stronger signal. In STD the weights are thus either w1=1, w2=0 or w1=0, w2=1. Information about the selection can be transmitted from the receiver to the transmitter using one bit of feedback information.
As a further example, consider WCDMA Mode 1. There the transmission of a signal sent on two channels is controlled by adjusting the phase difference between the channels. The phase difference can be adjusted in steps of 90 degrees. This means that the following combinations of weights w1 and w2 are possible:
These combinations define four possible feedback symbols. Two bits of feedback information are needed to transmit feedback information for WCDMA Mode 1. Mode 1 is also called 2-bit co-phasing.
As an even further example, consider WCDMA Mode 2. There the transmission of a signal sent on two channels is controlled by adjusting the phase difference between the channels and by selecting one of two predetermined ratios of the transmission powers of the two channels. In Mode 2, the one bit of feedback information is transmitted for indicating the selection of |w1|={square root}{square root over (0.2)}, |w2|={square root}{square root over (0.8)} or |w1|={square root}{square root over (0.8)}, |w2|={square root}{square root over (2)}. Three bits of feedback information define the phase difference of eimπ/4, m=0, . . . ,7. There are thus sixteen different feedback symbols in WCDMA Mode 2.
In the embodiments of the invention, binary feedback information about the feedback symbol to be used is transmitted as a feedback word. There is a predetermined mapping between the set of feedback symbols and the set of feedback words. Once a desired feedback symbol has been determined, it is possible to determine the respective feedback word. As mentioned above, in prior art solutions a Gray encoding for the mapping between the feedback symbols and the feedback words has been used, based on the assumption that Gray encoding is effective against errors in transmitting feedback information. A Gray encoding is a coding that minimizes the number of bit errors ensuing from a minimum Euclidean distance symbol error.
In feedback signaling, that is in transmitting feedback information, there is need to be prepared for errors in transmitting the feedback information. The effect of at least one possible transmission error in transmitting the feedback word can be taken into account. In an embodiment of the invention, this is done by minimizing the Euclidean distance of the symbol errors ensuing from a given number of feedback bit errors. The Euclidean distance of symbol errors ensuing from feedback bit errors affects the quality of the signal, whose transmission is controlled using the feedback information. In other words, the Euclidean distance of symbol errors affects the bit error rate in a dedicated channel where the feedback weight (symbol) is applied.
In an embodiment of the present invention, the mapping between the feedback symbols and the feedback words is selected so that the average squared Euclidean distance of feedback symbol errors ensuing from a given number of feedback bit errors is minimized. If there is set of mappings that provide the same average squared Euclidean distance for the feedback symbols errors, the maximum Euclidean distance of the feedback symbol errors ensuing from the given number of feedback errors is minimized.
In many embodiments of the invention, the given number of bit errors can be selected to be one. This is so because the probability of two or more bit errors is typically insignificant compared to the probability of one bit error.
It is possible to find suitable mappings by, for example, evaluating all possible mappings between a set of feedback symbols and a set of feedback words. A mapping with the minimum average squared Euclidean distance of feedback symbol errors ensuing from a given number of feedback bit errors is selected. If needed, the maximum Euclidean distances of feedback symbol errors ensuing from the given number of feedback bit errors are also evaluated for the mappings having the minimum average Euclidean distance. The mapping with minimum maximum distance among the ones with minimum average distance is chosen.
In a first embodiment of the invention, consider two-bit feedback words for controlling amplitude or jointly amplitude and phase of the transmission. That is, the feedback symbol is a quantized real number. The transmission to be controlled may be, for example, transmission from one antenna or transmission from two antennas.
The four feedback symbols relating to the four two-bit feedback words may be symbols of a four-level power amplitude modulation (4-PAM). It is clear that the feedback symbols need not be equally spaced in the feedback symbol constellation.
The average one bit error Euclidean distance for the mapping illustrated in
For amplitude control, the four feedback symbols may define four different amplitude levels. The amplitude levels may be equally spaced or at various distances. For joint amplitude and phase control, the four feedback symbols may define two different amplitude levels for two different phase differences.
As a comparative example,
Again the one bit error transitions are marked. The average one bit error Euclidean distance for the mapping illustrated in
In a second embodiment of the invention, three-bit feedback words are used to indicate eight different phase differences.
As a comparative example,
Performance in a simple feedback system employing two transmission antennas has been studied using simulations. As a concrete example of the second embodiment of the invention, a 3-bit co-phasing algorithm is considered, where the phase difference between two channels is fed back using 8-PSK quantization.
The legend in
In a third embodiment of the invention, four-bit feedback words are used for controlling jointly amplitude and phase. Furthermore, the non-Gray encoding is applied on the phase quantization. As a concrete example, consider WCDMA Mode 2, which applies 3-bit phase quantization (8-PSK) and one-bit amplitude quantization. A mapping, which minimizes the average squared Euclidean distance of feedback symbol errors ensuing from one bit feedback errors, is used in the phase quantization.
The SNR gains in the presence of feedback errors for both mappings are the same. This is a result of the fact that the average square Euclidean distance is the same for both the Gray encoding and for the third embodiment of the invention. The feedback scheme employing the third embodiment of the invention preserves the diversity gain better. The performance gains of using a feedback scheme in accordance with the third embodiment of the invention instead of using a feedback scheme employing Gray encoding can be found in Table 1. The gains are quite small, but it should be noted that they come for free.
In a fourth embodiment of the invention, amplitude and phase feedback are also controlled jointly. In the fourth embodiment, the non-Gray encoding is applied on the amplitude feedback. As an example, consider feedback information where two bits are for phase feedback and two bits are for amplitude feedback. For the amplitude feedback it is possible to use the prior art Gray encoding (see
The controller 925 uses a mapping, which is different from the mapping relating to Gray encoding and which takes into account possible transmission errors for the feedback information, for determining a feedback word to be sent to the first network element 910. This feedback is then sent typically unprotected over a wireless link (arrow 940 in
In a cellular system, the first network element 910 may be a base station (or a corresponding network element) of the cellular system. It is noted that in a cellular network element, the control of the radio resources may be provided in a separate network element. Such a separate network element is often called a radio resource controller. Alternatively, the feedback information may be processed locally in a base station. In a cellular system, the second network element 920 may be user equipment.
It is, however, appreciated that the first network element and the second network element may be any network elements of a communication system, where feedback information is provided for controlling transmission from the first network element to the second network element.
For determining the feedback symbol, which the first network element 910 should use in transmission control, the second network element 920 typically needs information about the channel coefficients. For this purpose, the controller 925 is typically configured to estimate channel coefficients of the reception channels.
Similarly as the first and second network elements in
The controller 975 is typically configured to determine channel information about the MIMO channel. In FDD systems the channel from the MIMO transmitter 960 to the MIMO receiver 970 is different from the channel in the opposite direction. In a lowly changing environment, where good channel estimates of the matrix channel exist at the MIMO receiver 970, part of this may be conveyed to the MIMO transmitter 960. Based on the feedback information, the target is to construct N≦min (NT, Nr) beams at the MIMO transmitter 960, which can be independently received at the MIMO receiver 970.
In a MIMO system, the feedback information typically represents channel properties at the MIMO receiver.
Above, different example of feedback information has been discussed. In general, the embodiments of the invention are applicable in any radio communication system, where phase feedback with more than 2 bits or amplitude feedback or joint phase/amplitude feedback with more than 1 bit is applied.
It is appreciated that the feedback may be based on long or short term information. The feedback information may describe channel information (phase, amplitude, power control) or any other information pertinent for setting up a communication link. The feedback information may thus be any digitized real or complex numbers.
The invention is not restricted to using any specific feedback symbols discussed above. In addition to the example given above, 16-QAM (quadrature amplitude modulation) symbols, for example, may be used as feedback symbols for controlling phase and amplitude jointly.
It is furthermore appreciated that although many specific examples above relate to controlling diversity transmission, the feedback information may be provided for controlling any transmission, including a transmission of a signal from a single antenna. Power control is one example of controlling a signal transmitted from a single antenna. The invention is furthermore applicable in providing feedback information in a MIMO system.
It is appreciated that the feedback information may indicate a feedback symbol, which the transmitter should use for controlling the transmission. Alternatively, the feedback information may describe the channel properties (phase, amplitude, received power) estimated at the receiver. In this case, the transmitter determines the proper manner to control the transmission based on the feedback information provided by the receiver.
It is also appreciated that although the examples above relate to feedback information indicating absolute quantities controlling transmission, the invention is applicable also for providing differential feedback information.
It is appreciated that feedback information may be generated in a communications system for controlling transmission from a communications device, for example, from a mobile station or from user equipment. Alternatively feedback information may be generated in a communications device for controlling transmission from a communications system to the communications device. Similarly, the transmission control based on feedback information may take place in a communication system or in a communications device. In other words, the invention is applicable for controlling transmission in the uplink direction or in the downlink direction in a cellular communications system.
It is furthermore appreciated that although the examples described above relate to a WCDMA system, the present invention is applicable in any system where feedback information is transmitted digitally.
Although preferred embodiments of the apparatus and method embodying the present invention have been illustrated in the accompanying drawings and described in the foregoing detailed description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.
Claims
1. A method for generating feedback information for controlling transmission from a transmitting end using a set of feedback symbols, said feedback information comprising a set of feedback words, the method comprising:
- determining at least one feedback symbol based on at least one signal received from a transmitting end; and
- determining a feedback word to be transmitted to the transmitting end, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
2. A method as defined in claim 1, wherein the step of determining the feedback word comprises determining a binary feedback word comprised in the feedback word by the mapping between said set of feedback symbols and said feedback words, the mapping minimizing an average square Euclidean distance of feedback symbol errors ensuing from a given number of feedback bit errors.
3. A method as defined in claim 1, wherein the step of determining the feedback word comprises determining a binary feedback word comprised in the feedback word by the mapping between said set of feedback symbols and said feedback words, the mapping minimizing an average square Euclidean distance of feedback symbol errors ensuing from one feedback bit error.
4. A method as defined in claim 1, wherein the step of determining the feedback word comprises determining a binary feedback word comprised in the feedback word by the mapping between said set of feedback symbols and said feedback words, the mapping belonging to a set of mappings minimizing an average square Euclidean distance of feedback symbols errors ensuing from a given number of feedback bit errors, the mapping further minimizing the maximum Euclidean distance of feedback symbol errors ensuing from the given number of feedback bit errors within said set of mappings.
5. A method as defined in claim 1, wherein the step of determining the feedback word comprises determining a binary feedback word comprised in the feedback word by the mapping between said set of feedback symbols and said feedback words, the mapping belonging to a set of mappings minimizing an average square Euclidean distance of feedback symbols errors ensuing from one feedback bit error, the mapping further minimizing the maximum Euclidean distance of feedback symbol errors ensuing from one feedback bit error.
6. A method as defined in claim 1, wherein in the step of determining the feedback word, the feedback word is determined using the mapping between said set of feedback symbols and said set of feedback words, feedback words of said set of feedback words being at least three bits long and feedback symbols of said set of feedback symbols defining various phases.
7. A method as defined in claim 1, wherein in the step of determining the feedback word, the feedback word is determined using the mapping between said set of feedback symbols and said set of feedback words, feedback words of said set of feedback words being at least two bits long and feedback symbols of said set of feedback symbols defining various amplitudes.
8. A method as defined in claim 1, wherein in the step of determining the feedback word, the feedback word is determined using the mapping between said set of feedback symbols and said set of feedback words, feedback words of said set of feedback words being at least two bits long and feedback symbols of said set of feedback symbols defining various amplitude and phase combinations.
9. A method as defined in claim 1, wherein the step of determining the feedback word comprises determining an at least two bits long first feedback word relating to various amplitudes and an at least one bit long second feedback word, the feedback word comprising said first feedback word and said second feedback word, said first feedback word being determined using a mapping between a set of at least two bits long first feedback words and said set of feedback symbols taking into account said at least one transmission error in transmitting the first feedback word.
10. A method as defined in claim 1, wherein the step of determining the feedback word comprises determining an at least three bits long first feedback word relating to various phases and an at least one bit long second feedback word, the feedback word comprising said first feedback word and said second feedback word, said first feedback word being determined using a mapping between a set of at least three bits long first feedback words and said set of feedback symbols taking into account said at least one transmission error in transmitting the first feedback word.
11. A method of transmitting a feedback word to a transmitting end, the method comprising:
- determining at least one feedback symbol based on at least one signal received from a transmitting end;
- determining a feedback word to be transmitted to the transmitting end, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding; and
- transmitting the determined feedback word to the transmitting end.
12. A method for receiving feedback information for controlling transmission from a transmitting end using a set of feedback symbols, said feedback information comprising a set of feedback words, the method comprising:
- receiving a feedback word; and
- determining a feedback symbol relating to a received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting a feedback word to a transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
13. A method of controlling transmission, said method comprising:
- receiving a feedback word;
- determining a feedback symbol relating to a received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting a feedback word to a transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding; and
- controlling transmission from the transmitting end based on a determined feedback symbol.
14. A method as defined in claim 13, wherein the step of controlling comprises using the determined feedback symbol directly in controlling transmission.
15. A method as defined in claim 13, wherein the step of controlling comprises using the determined feedback symbol directly in controlling transmission, said determined feedback symbol defining an absolute change to transmission.
16. A method as defined in claim 13, wherein the step of controlling comprises using the determined feedback symbol directly in controlling transmission, said determined feedback symbol defining a differential change to transmission.
17. A method as defined in claim 13, wherein the step of controlling comprises determining based on the feedback symbol channel properties estimated at a receiving end, said receiving end receiving transmission from said transmitting end, and controlling transmission based on determined channel properties.
18. A device for generating feedback information for controlling transmission from a transmitter using a set of feedback symbols, said feedback information comprising a set of feedback words, the device being configured
- to determine a feedback symbol based on at least one signal received from the transmitter, and
- to determine a feedback word to be transmitted, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the transmitter, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
19. A device as defined in claim 18, the device being further configured to transmit the determined feedback word.
20. A device as defined in claim 18, the device comprising a receiver for signals transmitted from the transmitter.
21. A device as defined in claim 18, the device comprising a network element for a communication system.
22. A device as defined in claim 18, the device comprising a communication device for communications via a communication system.
23. A device for receiving feedback information for controlling transmission from a transmitter using a set of feedback symbols, said feedback information comprising a set of feedback words, said set of feedback words being mapped onto said set of feedback symbols, the device being configured
- to receive a feedback word, and
- to determine a feedback symbol relating to a received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the received feedback word, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
24. A device as defined in claim 23, the device being further configured to control the transmission using a determined feedback symbol.
25. A device as defined in claim 23, the device comprising a transmitter.
26. A device as defined in claim 23, the device comprising a network element for a communication system.
27. A device as defined in claim 23, the device comprising a communication device for communications via a communication system.
28. A device comprising:
- first determining means for determining a feedback symbol based on at least one signal received from a transmitting end; and
- second determining means for determining a feedback word to be transmitted to the transmitting end, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
29. A device comprising:
- receiving means for receiving a feedback word; and
- determining means for determining a feedback symbol relating to the received feedback word using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting a feedback word to a transmitting end, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding.
30. A communication system comprising a first device for generating feedback information for controlling transmission from a second device comprised in the communications system,
- the first device being configured to determine a feedback symbol based on at least one signal received from the second device, and to determine a feedback word to be transmitted, said feedback word relating to a determined feedback symbol, using a mapping between a set of feedback symbols and a set of feedback words that takes into account an effect of at least one transmission error in transmitting the feedback word to the second device, said mapping between said set of feedback symbols and said set of feedback words being different from a mapping relating to Gray encoding, and the second device being configured to receive a feedback word, and to determine a feedback symbol relating to a received feedback word using said mapping between said set of feedback symbols and said set of feedback words.
Type: Application
Filed: Feb 17, 2004
Publication Date: Apr 7, 2005
Patent Grant number: 7363004
Applicant:
Inventor: Olav Tirkkonen (Helsinki)
Application Number: 10/778,207